FR2679078A1 - Electrical power supply device with a programmable characteristic - Google Patents

Abstract

It includes an energy source (1), a means (3) for controlling the voltage or the strength of the electric current applied to an electric load (2), a means (8) of measuring the strength or the voltage of the said current, an analogue-digital converter linked to the measurement means (8), a conversion table (9), the address input of which is linked to the analogue-digital converter and the output of which is linked to the control means (3), the conversion table (9) holding the data of the programmed characteristic.

Description

The present invention relates to a power supply device with

  programmable characteristic, and applies in particular to the simulation of electrical circuits and to the supply of electrical assemblies requiring high operational safety. We know that a supply is characterized by the curve of the electric intensity delivered as a function of

the output voltage.

  Power supplies currently known are divided into several types: laboratory power supplies with fixed or variable voltage, converters and

  continuous power supplies.

  The digital controls of these power supplies remain limited to the control of their output voltage or of the accepted limit current, their internal characteristic

  being neither programmable nor controllable.

  The object of the present invention is to remedy this deficiency by proposing a power supply with a programmable characteristic using a conventional supply and a DC-DC converter, such a supply making it possible to simulate the internal characteristic of any type of supply, by example of solar generators, and predict the operating parameters of a

Electrical Installation.

  The device which is the subject of the present invention is a power supply device with a programmable characteristic comprising a power source, a means for controlling the output voltage or intensity of this power source, an intensity sensor or source output voltage, an analog-digital converter connected to said sensor, a conversion table connected at the input to the analog-digital converter and at the output to the control and keeping

  the data of the programmed characteristic.

  The device according to the invention is presented according to two embodiments, one with voltage control, the other with intensity control. In both cases, it includes a control loop.

  The description which follows, made next to the

  attached drawing for explanatory purposes and in no way limitative, will allow a better understanding of the advantages, aims and

features of the invention.

  In the accompanying drawing, FIG. 1 represents an operating diagram of a first embodiment, with voltage

  controlled device of the invention.

  FIG. 2 represents an electronic diagram of

  realization of this first embodiment.

  FIG. 3 represents a diagram of operation of a second embodiment, with intensity

  controlled device of the invention.

  FIG. 4 represents an electronic diagram of

  realization of this second embodiment.

  If we refer to FIG. 1, we see represented therein an energy source 1, an electrical charge 2, a controlled voltage source 3 comprising a voltage control input 4, an energy input 5 connected to the source energy 1 and an output connected to the electrical load 2 by electrical connections 6 and 7, a digital current intensity measurement means 8 placed on the electrical connection 6, a conversion table 9 whose input is connected to the intensity sensor 8 and the output of which is connected to

  the control input 4 of the controlled voltage source 3.

  The energy source 1 is arbitrary and can consist of a stand-alone generator, a storage battery, a generator or a transformer-rectifier association coupled to the distribution network, or a supply of known type It supplies a direct current The electrical charge 2 is also arbitrary and corresponds to an electrical appliance or to a

Electrical Installation.

  The controlled voltage source 3 is adapted to deliver the energy which it receives from the energy source 1 according to a voltage whose value is fixed on its input of

tension control 4.

  The current intensity measuring means 8 measures the intensity of the current passing through the link 6 and transmits digital values to the conversion table 9 The conversion table 9, commonly known by its English name "look-up table" or LUT, is a memory whose address inputs are linked to data, here the numerical values leaving the measuring means 8 For each input value is memorized an output value The transfer function of a conversion table is pre -programmed and can

  take any form, continuous or discontinuous.

  According to the invention, the transfer function kept in the conversion table corresponds to the programmed characteristic of the programmable power supply, the information being stored either on a

  read only memory, or on a backed up RAM.

  It is understood that each intensity level measured by the measuring means 8 corresponds to a voltage level given by the conversion table 9, and therefore a voltage level between the links 6 and 7 at the output of the controlled voltage source. 3 The device thus formed provides a power supply with a programmable characteristic, the control of which concerns the intensity of the current and controls the voltage. In this way the internal characteristic of the device is programmable, the characteristic stored in the conversion table 9 here being the function which

  assigns a current to a voltage.

  It should be noted that the programming means of the conversion table are not shown in the figures. The conversion table 9 being a memory, all the known means for storing the characteristic data therein can be used. In particular, for programmable read only memory conversion tables, also called

  PROM, programming is done on a PROM programmer.

  A special connector can also be used to enter the characteristic data by means of an external computer. If we now refer to FIG. 2, we see there represented the electrical network 13, a DC voltage source 14, the controlled voltage source 3, interconnected successively, the load 2, connected by electrical connections 6 and 7 at the controlled voltage source 3, a means 8 for measuring the intensity of the current passing through the link 6 connected to an amplifier 15 with adjustable gain, an analog-digital converter 16, the conversion table 9, connected by its address bus 17 at the output of the analog to digital converter 16, a programmable timer 18 and a digital to analog converter 19 connected to the data output bus 21 of the conversion table 19, a modulator 20, connected to the output of the digital to analog converter 19 , the outputs of the programmable timer 18 and of the modulator 20 being connected to the control input 4 of the voltage source

ordered 3.

  The controlled voltage source 3 includes a chopper 22, two capacitors 23, a diode 24, all connected to the electrical connections 6 and 7, and an inductor 25 on the

  connection 7 The control input 4 is connected to the chopper 22.

  Referring to FIGS. 1 and 2, it can be seen that the energy source 1 consists of the network 13 and of the DC voltage source 14 The DC voltage source 14 generally consists of a rectifier and a pass filter -low. In FIG. 2, for explanatory purposes, two connection means between the analog-digital converter 9 and the control input 4 are presented: the programmable timer 18, on the one hand, and the digital analog converter 19 associated with the modulator 20, on the other hand Only one of these connections is necessary and the second is preferential. Measuring means 8 of current intensity

  crossing link 6 is here of hall effect, and of known type.

  It delivers a voltage proportional to the current measured.

  The programmable timer 18 consists of a circuit integrating programmable binary counters whose association and programming make it possible to generate a signal with a duty cycle directly controlled by the number N supplied by the conversion table 9 and representing the setpoint.

for the chopper 22.

  In combination with the modulator 20, the digital-analog converter 19 generates a variable duty cycle from an analog signal reconstituted from the same number N supplied by the conversion table 9 to the converter 19 The output of the converter 19 is compared by the modulator 20 has a ramp signal, according to an operation known per se, and the modulator 20 provides a discrete periodic signal with variable duty cycle, proportional to the reference number N. The chopper 22 is adapted to operate at high frequency so as to minimize the dimensions of the components forming the low-pass filter: inductance 25 and capacity 23 The chopper 22 is a step-down chopper It is controlled by a binary signal with variable duty cycle This is

  produced by the programmable timer 18.

  Referring now to FIG. 3, there is shown there an energy source 1, an electrical charge 2, an adjustable current source 10 comprising a current control input 11, an energy input 5 connected to the energy source 1 and an output connected to the electrical load 2 by electrical connections 6 and 7, a voltage sensor 12 placed between the electrical connections 6 and 7, a conversion table 9 whose input is connected to the voltage 12 and whose output is connected to the control input 11 of the

adjustable current source 10.

  The elements common to Figures 3 and 1 have the

  same functions as those presented with regard to FIG. 1.

  The adjustable current source 10 is adapted to deliver the energy which it receives from the energy source 1 according to an intensity whose value is fixed on its input of

intensity control 11.

  The voltage sensor 12 is adapted to give in digital form a value of the voltage between the connections 6

and 7.

  In comparison with FIG. 1, it is understood that this device produces a power supply with a programmable characteristic, the control of which concerns the voltage and

controls the intensity.

  The characteristic preserved in the conversion table 9 is here the intensity of the current as a function of the voltage. If we now refer to FIG. 4, we see there represented the electrical network 13, a DC voltage source 14, the controlled voltage source 10, interconnected successively, the load 2, connected by the electrical connections 6 and 7 at the controlled voltage source 10, a voltage measurement means 12 connected to the links 6 and 7 and to an amplifier 15 with adjustable gain, an analog-digital converter 16, the conversion table 9, connected by its address bus 17 to the output of the analog to digital converter 16, a programmable oscillator 26 and a digital to analog converter 19 connected to the data output bus 21 of the conversion table 9, an analog regulator 28 connected to the output of the digital to analog converter 19, a regulator with locking loop 27 connected to the programmable oscillator 26, the outputs of the analog regulator 28 and of the locking loop regulator 27 being connected to the input

  11 of the controlled voltage source 10.

  The controlled voltage source 10 comprises a chopper 22, two capacitors 23, a diode 24, all connected to the electrical connections 6 and 7, and an inductor 25 on the

  link 7 The control input 11 is connected to the chopper 22.

  Referring to FIGS. 3 and 4, it can be seen that the energy source 1 consists of the network 13 and of the DC voltage source 14 The DC voltage source 14 generally consists of a rectifier and a pass filter -low. In FIG. 4, for explanatory purposes, two connection means between the analog-digital converter 9 and the control input 11 are presented: the programmable oscillator 26 and the locking loop regulator 27, on the one hand, and the analog to digital converter 19 associated with the analog regulator 28, on the other hand Only one of these connections is necessary and the second is preferable because

  it causes little servo oscillation.

  It should be noted that the chopper being essentially a converter which imposes the voltage across the terminals of the load, when a controlled current source is produced, it is necessary to produce an internal servo loop constituted either by analog regulator 28, either

  the programmable oscillator 26 and the regulator 27.

  The programmable oscillator 26 consists of either a programmable timer used in astable mode or a programmable frequency divider based on binary counters. This oscillator provides a pilot frequency associated with the number N from the conversion table 9. The regulator with phase lock loop 27, commonly called according to the initials of its English name PLL, comprises a voltage-frequency converter and a phase comparator It equalizes the frequency coming from the programmable oscillator 26 with that of the voltage-frequency converter, at means of the phase comparator The input voltage of the converter is an image of the actual current measured. The signal leaving the phase comparator has a variable duty cycle and compatible with the control of the

chopper 22.

  The analog regulator 28 consists of a hysteresis effect comparator. It maintains the actual current in a narrow value band centered on the setpoint. The chopper 22 is here controlled by a binary signal whose frequency is representative of the controlled current This frequency is produced by the programmable oscillator 26 and controlled by the loop regulator

lock 27.

  The production of a power supply with a programmable characteristic operating both as a controlled current source and as a controlled voltage source, the combination of the embodiments presented with regard to FIGS. 2 and 4 is simple because many components are identical A simple switch would allow to choose the mode of control of the chopper On the other hand, the characteristics memorized in the conversion table 9 are symmetrical between the two embodiments The switch should therefore also control the area of the memory in which the table of functioning

conversion 9.

  One of the main applications of the device which is the subject of the present invention relates to the simulation of

  operation of autonomous electrical installations.

  For example, to simulate the operation of an electrical installation whose power supply is a solar generator, for space applications, it becomes possible to reproduce on the ground conditions of lighting of space from a database of measurements recorded over a defined period The characteristic of this generator is placed in the conversion table 9 By carrying out the first embodiment of the device, represented in FIG. 2, the variation in the illumination of the solar cell is simulated by variation of gain

  adjustable gain amplifier 15.

  This simulation allows the identification of the system in relation to this "illumination" input and the evaluation of performance by analysis of the response to standard inputs, index or harmonic responses in relation to the illumination. This simulation also makes it possible to reproduce in a few minutes variations in illumination during typical days, with or without passing clouds, for the sizing of the system in relation to the characteristics of the solar "deposit". For controlling this gain adjustment, it is preferable to use an adjustable gain amplifier 15 controlled for example by a voltage from a signal generator. Another amplification of the invention is the production of laboratory power supplies protected by their internal characteristic of short circuits and handling errors.

Claims (9)

  1) Power supply device with programmable characteristic comprising an energy source (1), a control means (3, 10) for the voltage or intensity of the electric current applied to an electric charge (2), a means for measuring (8, 12) the intensity or the voltage of said current, an analog-digital converter (16) connected to said measuring means (8, 12), a conversion table (9) whose input of address (17) is connected to the analog-digital converter (16) and the output of which is connected to the control means (3, 10), said conversion table (9) retaining the data of the programmed characteristic.   2) Device according to claim 1 characterized in that the control means (3) controls the voltage of the electric current applied to the electric load (2), the measuring means (8) measuring the intensity of the current passing through said load electric (2).   3) Device according to claim 2 characterized in that the control means (3) consists of a chopper (22) and a low-pass filter (23, 25), said chopper (22) being controlled   by a binary signal on its control input (4).   4) Device according to claim 3 characterized in that it comprises a digital analog converter (19) connected to the output of the conversion table (9) and a modulator (20) connected to the output of the digital to analog converter (19 ) and whose output is connected to the control input (4) of the chopper (22) so that the signal received by the control input (4) is a binary signal whose duty cycle is proportional to the value outgoing signal from the table conversion (9).   5) Device according to claim 3 characterized in that it comprises a programmable timer (18) connected to the output of the conversion table (9) and to the input (4) of the chopper (22), so that the signal received by the control input (4) is a binary signal whose duty cycle is proportional to the value of the signal leaving the table conversion (9).   6) Device according to claim 1 characterized in that the control means (10) controls the intensity of the current passing through the electric charge (2), the measuring means (12)   measuring the voltage applied to said electrical charge (2).   7) Device according to claim 6 characterized in that the control means (10) consists of a chopper (22) and a low-pass filter (23, 25). 8) Device according to claim 7 characterized in that it comprises a programmable oscillator (26) connected to the output of the conversion table (9) and a locking loop regulator (27) connected to the output of the oscillator programmable (26) and at the control input (11) of the chopper (22) so that the signal received by the control input (11) is a binary signal whose frequency is proportional to the value   of the signal leaving the conversion table (9).   9) Device according to claim 7 characterized in that it comprises a digital-analog converter (19) connected to the output of the conversion table (9) and a regulator   analog (28) connected to the output of the digital converter-   analog (19) and at the control input (11) of the chopper (22) so that the signal received by the control input (11) is a binary signal whose frequency is proportional to the   value of the signal leaving the conversion table (9).   ) Device according to any one of the claims   previous characterized in that the conversion table (9) consists of a programmable read only memory or a random access memory saved programmable.